ETC SI5600

Si5600
P R E L I M I N A R Y D A TA S H E E T
SiPHY ™ OC-192/STM-64 SONET/SDH TRANSCEIVER
Features
Complete low power, high speed, SONET/SDH transceiver with
integrated limiting amp, CDR, CMU, and MUX/DEMUX
! Data Rates Supported: OC-192/
! SONET Compliant Loop Timed
STM-64, 10GbE, and 10.7 Gbps FEC Operation
! Low Power Operation 1.2 W (typ)
! Programmable Slicing Level and
Sample Phase Adjustment
! DSPLL™ Based Clock Multiplier Unit
w/ Selectable Loop Filter Bandwidths ! SFI-4 Compliant Low Speed
Interface
! Integrated Limiting Amplifier
! Single Supply 1.8 V Operation
! Loss-of-Signal (LOS) Alarm
! 15 x 15 mm BGA Package
! Diagnostic and Line Loopbacks
Applications
!
Si5600
Bottom View
Ordering Information:
!
Sonet/SDH Transmission
Systems
Optical Transceiver Modules
! Sonet/SDH Test Equipment
See page 25.
Description
The Si5600 is a complete low-power transceiver for high-speed serial
communication systems operating between 9.9 Gbps and 10.7 Gbps. The receive
path consists of a fully integrated limiting amplifier, clock and data recovery unit
(CDR), and 1:16 deserializer. The transmit path combines a low jitter clock
multiplier unit (CMU) with a 16:1 serializer. The CMU uses Silicon Laboratories’
DSPLL™ technology to provide superior jitter performance while reducing design
complexity by eliminating external loop filter components. To simplify BER
optimization in long haul applications, programmable slicing, and sample phase
adjustment are supported.
The Si5600 operates from a single 1.8 V supply over the industrial temperature
range (–40°C to 85°C).
Functional Block Diagram
P H AS E AD J
RXLOL
LTR
S L IC E L V L
RXSQ LCH
LO S
RXM SBSEL
R X D IN
2
L im itin g
AMP
1:16
DEMUX
LOSLVL
CDR
32
REFSEL
T X C L K 1 6 IN
D S P L L TM
TX C M U
TXLO L
BW SEL
TX C LKO U T
TX S Q LC H
TXDO UT
RXCLK1
2
RXCLK2
R X C L K 2 D IV
RXCLK2DSBL
2
÷
2
2
16:1
MUX
TX C LK DS B L
÷
2
FIFO
LP TM
R E F R ATE
2
2
Loopback Control
REFCLK
R X D O U T [1 5 :0 ]
32
TX C LK 16O U T
T X C L K 1 6 IN
T X D IN [1 5 :0 ]
F IF O R S T
RESET
RESET
C o n tro l
F IF O E R R
LLBK
Preliminary Rev. 0.31 8/01
DLBK
TXM SBSEL
Copyright © 2001 by Silicon Laboratories
Si5600-DS031
This information applies to a product under development. Its characteristics and specifications are subject to change without notice.
Si5600
2
Preliminary Rev. 0.31
Si5600
TA B L E O F C O N T E N TS
Section
Page
Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Limiting Amplifier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Clock and Data Recovery (CDR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Deserialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Auxiliary Clock Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Data Squelch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
DSPLL™ Clock Multiplier Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Serialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Loop Timed Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Bias Generation Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Reference Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Transmit Differential Output Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Si5600 Pinout: 195-Pin BGA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pin Descriptions: Si5600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Ordering Guide . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Package Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contact Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Preliminary Rev. 0.31
4
12
12
12
12
13
13
13
13
14
14
15
15
15
16
17
19
25
26
28
3
Si5600
Electrical Specifications
Table 1. Recommended Operating Conditions
Parameter
Symbol
Ambient Temperature
LVTTL Output Supply Voltage
Si5600 Supply Voltage
Test Condition
Min*
Typ
Max*
Unit
TA
–40
25
85
°C
VDD33
1.71
—
3.47
V
VDD
1.71
1.8
1.89
V
*Note: All minimum and maximum specifications are guaranteed and apply across the recommended operating conditions.
Typical values apply at nominal supply voltages and an operating temperature of 25°C unless otherwise stated.
V
SIGNAL +
Differential
VICM, VOCM
SIGNAL –
I/Os
VIS
Single Ended Voltage
(SIGNAL +) – (SIGNAL –)
VID,VOD (VID = 2VIS)
Differential
Voltage Swing
Differential Peak-to-Peak Voltage
t
Figure 1. Differential Voltage Measurement
(RXDIN, RXDOUT, RXCLK1, RXCLK2, TXDIN, TXDOUT, TXCLKOUT, TXCLK16OUT, TXCLK16IN)
tsu
thd
TXDOUT,
TXDIN
tCH
TXCLKOUT,
TXCLK16IN
RXDOUT
RXCLK1
tcq1
tcq2
Figure 2. Data to Clock Delay
4
Preliminary Rev. 0.31
tCP
Si5600
80%
All Differential
IOs
20%
tF
tR
Figure 3. Rise/Fall Time Measurement
Table 2. DC Characteristics
(VDD = 1.8 V ±5%, TA = –40°C to 85°C)
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Supply Current
IDD
—
611
TBD
mA
Power Dissipation
PD
—
1.2
TBD
W
1.21
1.25
1.29
V
TBD
0.1
TBD
V
20
—
1.0
mV
(pk-pk)
.8
0.9
1.0
V
800
1000
1200
mV
(pk-pk)
Voltage Reference (VREF)
VREF
Common Mode Input Voltage (RXDIN)
VICM
Differential Input Voltage Swing (RXDIN)
Common Mode Output Voltage
(TXDOUT, TXCLKOUT)
VID
VREF driving
10 kΩ load
See Figure 1
VOCM
Differential Output Voltage Swing
(TXDOUT, TXCLKOUT), Differential pk-pk
VOD
LVPECL Input Voltage HIGH (REFCLK)
VIH
1.975
2.3
2.59
V
LVPECL Input Voltage LOW (REFCLK)
VIL
1.32
1.6
1.99
V
LVPECL Input Voltage Swing,
Differential pk-pk (REFCLK)
VID
250
—
2400
mV
(pk-pk)
LVPECL Internally Generated Input Bias
(REFCLK)
VIB
1.6
1.95
2.3
V
LVDS Input High Voltage
(TXDIN, TXCLK16IN)
VIH
—
—
2.4
V
LVDS Input Low Voltage
(TXDIN, TXCLK16IN)
VIL
0.0
—
—
V
LVDS Input Voltage, Single Ended pk-pk
(TXDIN, TXCLK16IN)
VISE
100
—
600
mV
(pk-pk)
LVDS Output High Voltage
(RXDOUT, RXCLK1, RXCLK2,
TXCLK16OUT)
VOH1
100 Ω Load
Line-to-Line
TBD
—
1.475
mV
LVDS Output Low Voltage
(RXDOUT, RXCLK1, RXCLK2,
TXCLK16OUT)
VOL1
100 Ω Load
Line-to-Line
0.925
—
TBD
V
LVDS Output Voltage, Differential pk-pk
(RXDOUT, RXCLK1, RXCLK2,
TXCLK16OUT)
VOSE
100 Ω Load
Line-to-Line,
Figure 1
500
—
800
mV
(pk-pk)
See Figure 1
Figure 1
Preliminary Rev. 0.31
5
Si5600
Table 2. DC Characteristics (Continued)
(VDD = 1.8 V ±5%, TA = –40°C to 85°C)
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
1.125
—
1.275
V
42
50
58
Ω
LVDS Common Mode Voltage
(RXDOUT, RXCLK1, RXCLK2,
TXCLK16OUT)
VCM
Input Impedance (TXDIN, TXCLK16IN,
REFCLK, RXDIN)
RIN
Output Short to GND
(RXDOUT, RXCLK1, RXCLK2,
TXCLK16OUT, TXDOUT, TXCLKOUT)
ISC(–)
—
25
TBD
mA
Output Short to VDD
(RXDOUT, RXCLK1, RXCLK2,
TXCLK16OUT, TXDOUT, TXCLKOUT)
ISC(+)
TBD
–100
—
µA
VDD33 = 3.3 V
—
—
0.8
V
VDD33 = 1.8 V
—
—
0.7
VDD33 = 3.3 V
2.0
—
—
V
VDD33 = 1.8 V
1.7
Each input to
common mode
LVTTL Input Voltage Low
(RXMSBSEL, RXCLK2DIV, RXCLK2DSBL,
RXSQLCH, REFSEL, LTR, RESET,
TXCLKDSBL, FIFORST, TXSQLCH,
BWSEL, TXMSBSEL, DLBK, LLBK, LPTM)
VIL2
LVTTL Input Voltage High
(RXMSBSEL, RXCLK2DIV, RXCLK2DSBL,
RXSQLCH, REFSEL, LTR, RESET,
TXCLKDSBL, FIFORST, TXSQLCH,
BWSEL, TXMSBSEL, DLBK, LLBK, LPTM)
VIH2
LVTTL Input Low Current
(RXMSBSEL, RXCLK2DIV, RXCLK2DSBL,
RXSQLCH, REFSEL, LTR, RESET,
TXCLKDSBL, FIFORST, TXSQLCH,
BWSEL, TXMSBSEL, DLBK, LLBK, LPTM)
IIL
—
—
10
µA
LVTTL Input High Current
(RXMSBSEL, RXCLK2DIV, RXCLK2DSBL,
RXSQLCH, REFSEL, LTR, RESET,
TXCLKDSBL, FIFORST, TXSQLCH,
BWSEL, TXMSBSEL, DLBK, LLBK, LPTM)
IIH
—
—
10
µA
LVTTL Input Impedance
(RXMSBSEL, RXCLK2DIV, RXCLK2DSBL,
RXSQLCH, REFSEL, LTR, RESET,
TXCLKDSBL, FIFORST, TXSQLCH,
BWSEL, TXMSBSEL, DLBK, LLBK, LPTM)
RIN
10
—
—
kΩ
VDD33 = 1.8 V
—
—
0.4
V
VDD33 = 3.3 V
—
—
0.4
VDD33 = 1.8 V
1.4
—
—
VDD33 = 3.3 V
2.4
—
—
LVTTL Output Voltage Low
(LOS, RXLOL, FIFOERR, TXLOL)
VOL2
LVTTL Output Voltage High
(LOS, RXLOL, FIFOERR, TXLOL)
VOH2
6
Preliminary Rev. 0.31
V
Si5600
Table 3. AC Characteristics (RXDIN, RXDOUT, RXCLK1, RXCLK2)
(VDD = 1.8 V ±5%, TA = –40°C to 85°C)
Parameter
Symbol
Output Clock Frequency
(RXCLK1)
Test Condition
Min
Typ
Max
Unit
—
622
667
MHz
tch/tcp, Figure 2
45
—
55
%
fclkout
Duty Cycle (RXCLK1, RXCLK2)
Output Rise and Fall Times
(RXCLK1, RXCLK2,RXDOUT)
tR,tF
Figure 3
—
50
—
ps
Data Invalid Prior to RXCLK1
tcq1
Figure 2
—
—
200
ps
Data Invalid After RXCLK1
tcq2
Figure 2
—
—
200
ps
400 kHz–10.0 GHz
10.0 GHz–16.0 GHz
18.7
TBD
—
—
—
—
dB
dB
SLICELVL = 200–800 mV
–20
—
20
mV
SLICELVL = 200–800 mV
–500
—
500
µV
VSLICE
–5
—
5
%
PHASEADJ = 200–800 mV
–45°
—
45
LOS Threshold Dynamic Range
LOSLVL = 200–800 mV
10
—
50
mV
pk-pk
LOS Threshold Offset3
(referred to RXDIN)
LOSLVL = 200–800 mV
–500
—
500
µV
VLOS
–5
—
5
%
Input Return Loss (RXIN)
Slicing Adjust Dynamic Range
1
Slicing Level Offset
(referred to RXDIN)
Slicing Level Accuracy
Sampling Phase Adjustment
LOS Threshold Accuracy
2
o
Note:
1. Slice level (referred to RXDIN) is calculated as follows: VSLICE = (SLICE_LVL – 0.4 " VREF)/15.
2. Sample Phase Offset is calculated as follows: PHASE OFFSET = 45° (PHASEADJ – 0.4 " VREF)/0.3
3. LOS Threshold voltage (referred to RXDIN) is calculated as follows: VLOS = 30 mV + (LOS_LVL – 0.4 " VREF)/15.
Preliminary Rev. 0.31
7
Si5600
Table 4. AC Characteristics (TXCLK16OUT, TXCLK16IN, TXCLKOUT, TXDIN, TXDOUT)
(VDD = 1.8 V ± 5%, TA = –40°C to 85°C)
Parameter
TXCLKOUT Frequency
Symbol
Test Condition
Min
Typ
Max
Unit
—
9.95
10.7
GHz
tch/tcp, Figure 2
45
—
55
%
fclkout
TXCLKOUT Duty Cycle
Output Rise Time
(TXCLKOUT, TXDOUT)
tR
Figure 3
—
25
—
ps
Output Fall Time
(TXCLKOUT, TXDOUT)
tF
Figure 3
—
25
—
ps
TXCLKOUT Setup to TXDOUT
tsu
Figure 2
25
—
—
ps
TXCLKOUT Hold From TXDOUT
thd
Figure 2
25
—
—
ps
400 kHz–10 GHz
10 GHz–16 GHz
TBD
TBD
—
—
—
—
dB
dB
—
622
667
MHz
40
—
60
%
Output Return Loss
TXCLK16OUT Frequency
fCLKIN
TXCLK16OUT Duty Cycle
tch/tcp, Figure 2
TXCLK16OUT Rise & Fall Times
tR,tF
100
—
300
ps
TXDIN Setup to TXCLK16IN
tDSIN
—
—
300
ps
TXDIN Hold from TXCLK16IN
tDHIN
—
—
300
ps
TXCLK16IN Frequency
fCLKIN
—
622
667
MHz
40
—
60
%
100
—
300
ps
TXCLK16IN Duty Cycle
TXCLK16IN Rise & Fall Times
8
tch/tcp, Figure 2
tR,tF
Preliminary Rev. 0.31
Si5600
Table 5. AC Characteristics (Receiver PLL)
(VDD = 1.8 V ± 5%, TA = –40°C to 85°C)
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Jitter Tolerance
JTOL(PP)
f = 2.4 kHz
15
30
—
UIpp
f = 24 kHz
1.5
3.0
—
UIpp
f = 400 kHz
1.5
3.0
—
UIpp
f = 4 MHz
0.15
0.3
—
UIpp
—
—
20
µs
REFRATE = 1
—
622
667
MHz
REFRATE = 0
—
155
167
MHz
Acquisition Time
TAQ
Input Reference Clock Frequency RCFREQ
Reference Clock Duty Cycle
RCDUTY
40
50
60
%
Reference Clock Frequency
Tolerance
RCTOL
–100
—
100
ppm
Frequency Difference at which
Receive PLL goes out of Lock
(REFCLK compared to the
divided down VCO clock)
LOL
TBD
600
1000
ppm
Frequency Difference at which
Receive PLL goes into Lock
(REFCLK compared to the
divided down VCO clock)
LOCK
TBD
300
TBD
ppm
Note: Bellcore specifications: GR-1377-CORE, Issue 5, December 1998.
Preliminary Rev. 0.31
9
Si5600
Table 6. AC Characteristics (Transmitter Clock Multiplier Characteristics)
(VDD = 1.8 V ± 5%, TA = –40°C to 85°C)
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Jitter Generation—Deterministic
JDET(PP)
PRBS 23
—
0.020
TBD
UIPP
—
0.005
TBD
UIRMS
BWSEL = 0
—
—
12
kHz
BWSEL = 1
—
—
50
kHz
—
0.05
0.1
dB
Jitter Generation—Random
JGEN(RMS)
Jitter Transfer Bandwidth
JBW
Jitter Transfer Peaking
TAQ
Valid REFCLK
—
15
20
mS
RCFREQ
REFRATE = 1
—
622
667
MHz
REFRATE = 0
—
155
167
MHz
RCDUTY
40
—
60
%
RCTOL
–100
—
100
ppm
Acquisition Time
Input Reference Clock Frequency
Input Reference Clock Duty
Cycle
Input Reference Clock Frequency
Tolerance
Note: Bellcore specifications: GR-1377-CORE, Issue 5, December 1998.
Table 7. Absolute Maximum Ratings
Parameter
Symbol
Value
Unit
VDD
–0.5 to TBD
V
VDD33
–0.5 to 3.6
V
VDIF
–0.3 to (VDD+ 0.3)
V
±50
mA
DC Supply Voltage
LVTTL Input Voltage
Differential Input Voltages
Maximum Current any Output PIN
Operating Junction Temperature
TJCT
–55 to 150
°C
Storage Temperature Range
TSTG
–55 to 150
°C
Package Temperature
(soldering 10 seconds)
275
°C
ESD HBM Tolerance (100 pf, 1.5 kΩ)
TBD
V
Note: Permanent device damage may occur if the above Absolute Maximum Ratings are exceeded. Functional operation
should be restricted to the conditions as specified in the operational sections of this data sheet. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
Table 8. Thermal Characteristics
Parameter
Thermal Resistance Junction to Ambient
10
Symbol
Test Condition
Value
Unit
ϕJA
Still Air
38
°C/W
Preliminary Rev. 0.31
Si5600
RXCLK2DSBL
RXCLK2DIV
RXMSBSEL
TXMSBEL
DLBK
LLBK
BWSEL
LPTM
RXSQLCH
TXSQLCH
REFRATE
REFSEL
TXCLKDSBL
LTR
LVTTL
Control Inputs
FIFO Over/Underflow
FIFOERR
FIFORST
TXLOL
Loss-of-Lock
Indicator
RXLOL
RESET
Loss-of-Signal
Indicator
LOS
0.033 µF
High Speed
Serial Input
RXDOUT±
RXDIN±
Si5600
LVPECL Reference
Clock
16
RXCLK1±
LVDS Recovered
Low Speed
Clock
REFCLK
RXCLK2±
LVDS Parallel Data
16
Input
LVDS Recovered
Parallel Data
0.033 µF
High Speed
Serial Data Output
TXDOUT±
TXDIN±
0.033 µF
TXCLKOUT±
High Speed
Clock Output
TXCLK16OUT±
Low Speed
Clock Output
RXREXT
GND
VREF
VDD
TXREXT
PHASEADJ
SLICELVL
TXCLK16IN±
LOSLVL
LVDS Data Clock
Input
Voltage Reference
Output (1.25 V)
0.1 µF
VDD
2200 pF
Loss-of-Signal Data Slice
Level Set
Level Set
Sampling Phase
Level Set
20 pF
Figure 4. Si5600 Typical Application Circuit
Preliminary Rev. 0.31
11
Si5600
Functional Description
LOSLVL pin, and VREF is reference voltage output on
the VREF pin.
The Si5600 transceiver is a low power, fully integrated
serializer/deserializer that provides significant margin to
all SONET/SDH jitter specifications. The device
operates from 9.9–10.7 Gbps making it suitable for OC192/STM-64, 10GbE, and OC-192/STM-64 applications
that use 15/14 forward error correction (FEC) coding.
The low speed receive/transmit interface uses LVDS I/
Os that are compliant to the Optical Interface Forum’s
SFI-4 standard.
The LOS detection circuitry is disabled by tieing the
LOSLVL input to the supply (VDD). This forces the LOS
output high.
Receiver
The receiver within the Si5600 includes a precision
limiting amplifier, high jitter tolerance clock and data
recovery unit (CDR), and 1:16 demultiplexer. In
addition, programmable data slicing and sampling
phase adjustment are provided to support bit-error-rate
(BER) optimization for long haul applications.
Limiting Amplifier
The Si5600 incorporates a high sensitivity limiting
amplifier with sufficient gain to directly accept the output
of transimpedance amplifiers. High sensitivity is
achieved by using a digital calibration algorithm to
cancel out amplifier offsets. This algorithm achieves
superior offset cancellation by using statistical
averaging to remove noise that may degrade more
traditional calibration routines.
The limiting amplifier provides sufficient gain to fully
saturate with input signals that are less than 20 mV
peak-to-peak differential. In addition, input signals that
exceed 1 V peak-to-peak differential will not cause any
performance degradation.
Loss-of-Signal (LOS) Detection
The limiting amplifier includes circuitry that generates a
loss-of-signal (LOS) alarm when the input signal
amplitude on RXDIN falls below an externally controlled
threshold. The Si5600 can be configured to drive the
LOS output low when the differential input amplitude
drops below a threshold set between ~10 mV and
50 mV pk-pk differential. Approximately 3 dB of
hysteresis prevents unnecessary switching on LOS.
The LOS threshold is set by applying a voltage between
0.20 V and 0.80 V to the LOSLVL input. The voltage
present on LOSLVL maps to an input signal threshold
as follows:
( V LOSLVL – 0.4xVREF )
V LOS = --------------------------------------------------------------- + 30 mV
15
Slicing Level Adjustment
To support applications that require BER optimization,
the limiting amplifier provides circuitry that supports
adjustment of the 0/1 decision threshold (slicing level)
over a range of ±20 mV when referred to the internally
biased RXDIN input. The slicing level is set by applying
a voltage between 0.20 V and 0.80 V to the SLICELVL
input. The voltage present on SLICELVL sets the slicing
level as follows:
( V SLICE – 0.4xVREF )
V LEVEL = ----------------------------------------------------------15
VLEVEL is the slicing level referred to the RXDIN input,
VSLICE is the voltage applied to the SLICE_LVL pin, and
VREF is reference voltage output on the VREF pin.
The slicing level adjustment may be disabled by tieing
the SLCLVL input to the supply (VDD). When slicing is
disabled, the slicing offset is set to 0.0 V relative to
internally biased input common mode voltage for
RXDIN.
Clock and Data Recovery (CDR)
The Si5600 uses an integrated CDR to recover clock
and data from a non-return to zero (NRZ) signal input on
RXDIN. The recovered data clock is used to regenerate
the incoming data by sampling the output of the limiting
amplifier at the center of the NRZ bit period. The
recovered clock and data is then deserialized by a 1:16
demultiplexer and output via a LVDS compatible low
speed interface (RXDOUT[15:0], RXCLK1, and
RXCLK2).
Sample Phase Adjustment
In applications where it is not desirable to recover data
by sampling in the center of the data eye, the Si5600
supports adjustment of the CDR sampling phase across
the NRZ data period. When sample phase adjustment is
enabled, the sampling instant used for data recovery
can be moved over a range of ±45° relative to the center
of the incoming NRZ bit period. Adjustment of the
sampling phase is desirable when data eye distortions
are introduced by the transmission medium.
The sample phase is set by applying a voltage between
0.20 V and 0.80 V to the PHASEADJ input. The voltage
present on PHASEADJ maps to sample phase offset as
follows:
VLOS is the differential pk-pk LOS threshold referred to
the RXDIN input, VLOSLVL is the voltage applied to the
12
Preliminary Rev. 0.31
Si5600
45°x ( V PHASE – 0.4xVREF )
Phase Offset = -------------------------------------------------------------------------0.30
Phase Offset is the sampling offset in degrees from the
center of the data eye, VPHASE is the voltage applied to
the PHASEADJ pin, and VREF is reference voltage
output on the VREF pin. A positive phase offset will
adjust the sampling point to lead the default sampling
point in the center of the data eye, and a negative phase
offset will adjust the sampling point to lag the default
sampling point.
Data recovery using a sampling phase offset is disabled
by tieing the PHASEADJ input to the supply (VDD). This
forces a phase offset of 0° to be used for data recovery.
Lock Detect
The Si5600 provides lock-detect circuitry that indicates
whether the PLL has achieved frequency lock with the
incoming data. This circuit compares the frequency of a
divided down version of the recovered clock with the
frequency of the supplied reference clock (REFCLK). If
the recovered clock frequency deviates from that of the
reference clock by the amount specified in Table 5 on
page 9, the PLL is declared out of lock, and the loss-oflock (RXLOL) pin is asserted. In this state, the PLL will
try to reacquire lock with the incoming data stream.
During reacquisition, the recovered clock frequency
(RXCLK1 and RXCLK2) will drift over a ±1000 ppm
range relative to the supplied reference clock. The
RXLOL output will remain asserted until the recovered
clock frequency is within the REFCLK frequency by the
amount specified in Table 5 on page 9.
output bus RXDOUT[15:0]. The mapping of the receive
bits to the output data word is controlled by the
RXMSBSEL input. If RXMSBSEL is tied low, the first bit
received is output on RXDOUT0 and the following bits
are output in order on RXDOUT1 through RXDOUT15.
If RXMSBSEL is tied high, the first bit received is output
on RXDOUT15, and the following bits are output in
order on RXDOUT14 through RXDOUT0.
Auxiliary Clock Output
To support the widest range of system timing
configurations, a second clock output is provided on
RXCLK2. This output can be configured to provide a
clock that is a 1/16th or 1/64th submultiple of the high
speed recovered clock. The divide factor used to
generate RXCLK2 is controlled via the RXCLKDIV2
input as described in "Pin Descriptions: Si5600‚" on
page 19. In applications which do not use RXCLK2, this
output can be powered down by forcing the
RSCLK2DSBL input high.
Data Squelch
During some system error conditions, such as LOS, it
may be desirable to force the receive data output to 0 in
order to avoid propagation of erroneous data into the
downstream electronics. In these applications, the
Si5600 provides a data squelching control input,
RXSQLCH. When this input is active low, the data on
RXDOUT will be forced to 0. Data squelch is disabled if
the device is operating in diagnostic loopback mode
(DLBK = 0).
Lock-to-Reference
Transmitter
In applications where it is desirable to maintain a stable
output clock during an alarm condition like loss-ofsignal, the lock-to-reference input (LTR) can be used to
force a stable output clock. When LTR is asserted, the
CDR is prevented from acquiring the data signal and the
CDR will lock the RXCLKOUT1 and RXCLKOUT2
outputs to the provided REFCLK. In typical applications,
the LOS output would be tied to the LTR input to force a
stable output clock.
The transmitter consists of a low jitter, clock multiplier
unit (CMU) with a 16:1 serializer. The CMU uses a
phase-locked loop (PLL) architecture based on Silicon
Laboratories’ proprietary DSPLL™ technology. This
technology is used to generate ultra-low jitter clock and
data outputs that provide significant margin to the
SONET/SDH specifications. The DSPLL architecture
also utilizes a digitally implemented loop filter that
eliminates the need for external loop filter components.
As a result, sensitive noise coupling nodes that typically
cause degraded jitter performance in crowded PCB
environments are removed.
Deserialization
The Si5600 uses a 1:16 demultiplexer to deserialize the
high speed input. The deserialized data is output on a
16-bit parallel data bus RXDOUT[15:0] synchronous
with the rising edge of RXCLK1. This clock output is
derived by dividing down the recovered clock by a factor
of 16.
Serial Input to Parallel Output Relationship
The Si5600 provides the capability to select the order in
which the received serial data is mapped to the parallel
The DSPLL™ also reduces the complexity and
performance requirements of reference clock
distribution strategies for OC-192/STM-64 optical port
cards. This is possible because the DSPLL provides
selectable wideband and narrowband loop filter settings
that allow the user to set the jitter attenuation
characteristics of the CMU to accommodate reference
clock sources that have a high jitter content. Unlike
Preliminary Rev. 0.31
13
Si5600
traditional analog PLL implementations, the loop filter
bandwidth is controlled by a digital filter inside the
DSPLL and can be changed without any modification to
external components.
DSPLL™ Clock Multiplier Unit
The Si5600’s clock multiplier unit (CMU) uses Silicon
Laboratories’ proprietary DSPLL technology to generate
a low jitter, high frequency clock source capable of
producing a high speed serial clock and data output with
significant margin to the SONET/SDH specifications.
This is achieved by using a digital signal processing
(DSP) algorithm to replace the loop filter commonly
found in analog PLL designs. This algorithm processes
the phase detector error term and generates a digital
control value to adjust the frequency of the voltage
controlled oscillator (VCO). Because external loop filter
components are not required, sensitive noise entry
points are eliminated, thus making the DSPLL less
susceptible to board-level noise sources. Therefore,
SONET/SDH jitter compliance is easier to attain in the
application.
Programmable Loop Filter Bandwidth
The digitally implemented loop filter allows for two
bandwidth settings that provide either wideband or
narrowband jitter transfer characteristics. The filter
bandwidth is selected via the BWSEL control input. In
traditional PLL implementations, changing the loop filter
bandwidth would require changing the values of
external loop filter components.
In narrowband mode, a loop filter cutoff of 12 kHz is
provided. This setting makes the Si5600 more tolerant
to jitter on the reference clock source. As a result,
distribution circuitry used to generate the physical layer
reference
clocks
can
be
simplified
without
compromising jitter margin to the SONET/SDH
specification.
In wideband mode, the loop filter provides a cutoff of
50 kHz. This setting is desirable in applications where
the reference clock is provided by a low jitter source like
the Si5364 Clock Synchronization IC or Si5320
Precision Clock Multiplier/Jitter Attenuator IC. This
allows the DSPLL to more closely track the precision
reference source, resulting in the best possible jitter
performance.
Serialization
The Si5600 includes serialization circuitry that
combines a FIFO with a parallel to serial shift register.
Low speed data on the parallel input bus, TXDIN[15:0],
is latched into the FIFO on the rising edge of
TXCLK16IN. The data in the FIFO is clocked into the
14
shift register by an output clock, TXCLK16OUT, that is
produced by dividing down the high speed transmit
clock, TXCLKOUT, by a factor of 16. The TXCLK16OUT
clock output is provided to support 16-bit word transfers
between the Si5600 and upstream devices using a
counter clocking scheme. The high-speed serial data
stream is clocked out of the shift register using
TXCLKOUT.
Input FIFO
The Si5600 integrates a FIFO to decouple data
transferred into the FIFO via TXCLK16IN from data
transferred into the shift register via TXCLK16OUT. The
FIFO is eight parallel words deep and accommodates
any static phase delay that may be introduced between
TXCLK16OUT and TXCLK16IN in counter clocking
schemes. Furthermore, the FIFO will accommodate a
phase drift or wander between TXCLK16IN and
TXCLK16OUT of up to three parallel data words.
The FIFO circuitry indicates an overflow or underflow
condition by asserting FIFOERR high. This output can
be used to recenter the FIFO read/write pointers by
tieing it directly to the FIFORST input. The Si5600 will
also recenter the read/write pointers after the device’s
power on reset, external reset via RESET, and each
time the DSPLL transitions from an out of lock state to a
locked state (TXLOL transitions from low to high).
Parallel Input To Serial Output Relationship
The Si5600 provides the capability to select the order in
which data on the parallel input bus is transmitted
serially. Data on this bus can be transmitted MSB first or
LSB first depending on the setting of TXMSBSEL. If
TXMSBSEL is tied low, TXDIN0 is transmitted first
followed in order by TXDIN1 through TXDIN15. If
TXMSBSEL is tied high, TXDIN15 is transmitted first
followed in order by TXDIN14 through TXDIN0. This
feature simplifies board routing when ICs are mounted
on both sides of the PCB.
Transmit Data Squelch
To prevent the transmission of corrupted data into the
network, the Si5600 provides a control pin that can be
used to force TXDOUT to 0. By driving TXSQLCH low,
the high speed serial output, TXDOUT will be forced to
0. Transmit data squelching is disabled when the device
is in line loopback mode (LLBK = 0).
Clock Disable
The Si5600 provides a clock disable pin, TXCLKDSBL,
that is used to disable the high-speed serial data clock
output, TXCLKOUT. When the TXCLKDSBL pin is
asserted, the positive and negative terminals of
CLKOUT are tied to 1.5 V through 50 Ω on-chip
resistors. This feature is used to reduce power
Preliminary Rev. 0.31
Si5600
consumption in applications that do not use the high
speed transmit data clock.
Loop Timed Operation
The Si5600 may be configured to provide SONET/SDH
compliant loop timed operation. When LPTM is asserted
high, the transmit clock and data timing is derived from
the recovered clock output by the CDR. This is achieved
by dividing down the recovered clock and using it as a
reference source for the transmit CMU. This will
produce a transmit clock and data that are locked to the
timing recovered from the received data path. In this
mode, a narrow band loop filter setting is
recommended.
Diagnostic Loopback
The Si5600 supports diagnostic loopback which
establishes a loopback path from the serializer output to
the deserializer input. This provides a mechanism for
looping back data input via the low speed transmit
interface TXDIN to the low speed receive data interface
RXDOUT. This mode is enabled by forcing DLBK low.
Line Loopback
The Si5600 supports line loopback which establishes a
loopback path from the high speed receive input to the
high speed transmit output. This provides a mechanism
for looping back the high-speed clock and data
recovered from RXDIN to the transmit data output
TXDOUT and clock TXCLKOUT. This mode is enabled
by forcing LLBK low.
Bias Generation Circuitry
The Si5600 makes use of two external resistors,
RXREXT and TXREXT, to set internal bias currents for
the receive and transmit sections of the Si5600. The
external resistors allows precise generation of bias
currents that significantly reduce power consumption.
The bias generation circuitry requires 3.09 kΩ (1%)
resistors connected between RXREXT/TXREXT and
GND.
reference clock submultiples of the data rate.
The Si5600 supports operation with two selectable
reference clock sources. The first configuration uses an
externally provided reference clock that is input via
REFCLK. The second configuration uses the parallel
data clock, TXCLK16IN, as the reference clock source.
When using TXCLK16IN as the reference source, the
narrowband loop filter setting in the CMU may be
preferable to remove jitter that may be present on the
data clock. The selection of reference clock source is
controlled via the REFSEL input.
The CMU in the Si5600’s transmit section multiplies up
the provided reference to the serial transmit data rate.
When the CMU has achieved lock with the selected
reference, the TXLOL output will be driven high.The
CDR in the receive section of the Si5600 uses a
reference clock to center the PLL frequency so that it is
close enough to the data frequency to achieve lock with
the incoming data. When the CDR has locked to the
data, RXLOL is driven high.
Reset
The Si5600 is reset by holding the RESET pin low for at
least 1 µs. When RESET is asserted low, the input FIFO
pointers reset and the digital control circuitry initializes.
When RESET transitions high to start normal operation,
the CMU will be calibrated.
Voltage Reference Output
The Si5530 provides an output voltage reference that
can be used by an external circuit to set the LOS
threshold, slicing level, or sampling phase adjust. One
possible implementation would use a resistor divider to
set the control voltage for LOSLVL, SLICELVL, or
PHASEADJ. A second alternative would use a DAC to
set the control voltage. Using this approach, VREF
would be used to establish the range of a DAC output.
The reference voltage is nominally 1.25 V.
Reference Clock
The Si5600 is designed to operate with reference clock
sources that are either 1/16th or 1/64th the desired
transceiver data rate. The device will support operation
with data rates between 9.9 Gbps and 10.7 Gbps and
the reference clock should be scaled accordingly. For
example, to support 10.66 Gbps operation the reference
clock source would be approximately 167 MHz or
666 MHz. The REFRATE input pin is used to configure
the device for operation with one of the two supported
Preliminary Rev. 0.31
15
Si5600
Transmit Differential Output Circuitry
The Si5600 utilizes a current-mode logic (CML) architecture to drive the high speed serial output clock and data on
TXCLKOUT and TXDOUT. An example of output termination with ac coupling is shown in Figure 5. In applications
where direct dc coupling is possible, the 250 nF capacitors may be omitted. The differential peak-to-peak voltage
swing of the CML architecture is listed in Table 2 on page 5.
1.5 V
50 Ω
VDD
50 Ω
50 Ω
250 nF
Zo = 50 Ω
250 nF
Zo = 50 Ω
50 Ω
VDD
24 mA
Figure 5. CML Output Driver Termination (TXCLKOUT, TXDOUT)
16
Preliminary Rev. 0.31
Si5600
Si5600 Pinout: 195 BGA
14
13
12
11
10
9
8
7
6
5
4
3
2
1
RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT
[10]+
[8]–
[8]+
[6]–
[6]+
[4]–
[4]+
[2]–
[2]+
[0]–
[0]+
RX
CLK[1]–
RX
CLK[1]+
RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT
[10]–
[9]–
[9]+
[7]–
[7]+
[5]–
[5]+
[3]–
[3]+
[1]–
[1]+
RX
CLK[2]–
RX
CLK[2]+
GND
B
A
RXDOUT RXDOUT
[12]+
[11]+
RXCLK2
DIV
RXREXT
NC
RXSQLCH
RXCLK2
DSBL
RSVD_
GND
RSVD_
GND
VREF
SLICELVL LOSLVL
GND
GND
C
RXDOUT RXDOUT
[12]–
[11]–
RXMSB
SEL
GND
GND
GND
GND
GND
GND
GND
PHASEADJ
RSVD_
GND
GND
RXDIN+
D
RXDOUT RXDOUT
[14]+
[13]+
RSVD_
GND
GND
VDD
VDD
VDD
VDD
VDD
VDD
RSVD_
VDD33
LTR
GND
RXDIN–
E
RXDOUT RXDOUT
[14]–
[13]–
DLBK
GND
VDD
VDD
VDD
VDD
VDD
VDD
RSVD_
GND
RXLOL
GND
GND
F
REF
CLK+
RXDOUT
[15]+
RSVD_
VDD33
GND
VDD
VDD
VDD
VDD
VDD
VDD
RESET
LOS
GND
TXCLKOUT+
G
REF
CLK–
RXDOUT
[15]–
LLBK
GND
VDD
VDD
VDD
VDD
VDD
VDD
REFRATE
VDD33
GND
TXCLKOUT–
H
TXDIN
[14]+
TXDIN
[15]+
LPTM
GND
VDD
VDD
VDD
VDD
VDD
VDD
GND
GND
GND
GND
J
TXDIN
[14]–
TXDIN
[15]–
TXCLK
DSBL
GND
VDD
VDD
VDD
VDD
VDD
VDD
RSVD_
GND
FIFOERR
GND
TXDOUT+
K
TXDIN
[12]+
TXDIN
[13]+
REFSEL
GND
GND
GND
GND
GND
GND
GND
NC
TXREXT
GND
TXDOUT–
L
TXDIN
[12]–
TXDIN
[13]–
TXSQLCH
RSVD_
GND
RSVD_
GND
TXMSB
SEL
RSVD_
GND
BWSEL
FIFORST
TXLOL
GND
GND
GND
GND
M
TXDIN
[11]+
TXDIN
[11]–
TXDIN
[9]+
TXDIN
[9]–
TXDIN
[7]+
TXDIN
[7]–
TXDIN
[5]+
TXDIN
[5]–
TXDIN
[3]+
TXDIN
[3]–
TXDIN
[1]+
TXDIN
[1]–
TXCLK16 TXCLK16
IN+
IN–
N
TXDIN
[10]+
TXDIN
[10]–
TXDIN
[8+]
TXDIN
[8]–
TXDIN
[6]+
TXDIN
[6]–
TXDIN
[4]+
TXDIN
[4]–
TXDIN
[2]+
TXDIN
[2]–
TXDIN
[0]+
TXDIN
[0]–
TXCLK16 TXCLK16
OUT+
OUT–
P
Bottom View
Figure 6. Si5600 Pin Configuration (Bottom View)
Preliminary Rev. 0.31
17
Si5600
1
A
2
3
4
5
6
7
8
RX
CLK1+
RX
CLK1-
RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT
[10]+
[8]–
[8]+
[6]–
[6]+
[0]+
[0]–
[2]+
[2]–
[4]+
[4]–
RX
CLK[2]–
RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT RXDOUT
[9]+
[9]–
[10]–
[7]–
[7]+
[5]–
[5]+
[1]+
[1]–
[3]+
[3]–
B
GND
RX
CLK[2]+
C
GND
GND
LOSLVL SLICELVL
VREF
RSVD_
GND
RSVD_
GND
D
RXDIN+
GND
RSVD_
GND
PHASE
ADJ
GND
GND
GND
GND
E
RXDIN–
GND
LTR
RSVD_
VDD33
VDD
VDD
VDD
F
GND
GND
RXLOL
RSVD_
GND
VDD
VDD
G
TXCLKOUT+
GND
LOS
RESET
VDD
H
TXCLKOUT–
GND
VDD33
REFRATE
J
GND
GND
GND
K
TXDOUT+
GND
L
TXDOUT–
M
GND
9
10
11
12
14
NC
RXREXT
RXCLK2
DIV
RXDOUT RXDOUT
[11]+
[12]+
GND
GND
GND
RXMSB
SEL
RXDOUT RXDOUT
[11]–
[12]–
VDD
VDD
VDD
GND
RSVD_
GND
RXDOUT RXDOUT
[13]+
[14]+
VDD
VDD
VDD
VDD
GND
DLBK
RXDOUT RXDOUT
[13]–
[14]–
VDD
VDD
VDD
VDD
VDD
GND
RSVD_
VDD33
RXDOUT
[15]+
REF
CLK+
VDD
VDD
VDD
VDD
VDD
VDD
GND
LLBK
RXDOUT
[15]–
REF
CLK–
GND
VDD
VDD
VDD
VDD
VDD
VDD
GND
LPTM
TXDIN
[15]+
TXDIN
[14]+
FIFOERR
RSVD_
GND
VDD
VDD
VDD
VDD
VDD
VDD
GND
TXCLK
DSBL
TXDIN
[15]–
TXDIN
[14]–
GND
TXREXT
NC
GND
GND
GND
GND
GND
GND
GND
REFSEL
TXDIN
[13]+
TXDIN
[12]+
GND
GND
GND
TXLOL
FIFORST
BWSEL
RSVD_
GND
TXMSB
SEL
RSVD_
GND
RSVD_
GND
TXSQLCH
TXDIN
[13]–
TXDIN
[12]–
RXCLK2
RXSQLCH
DSBL
N
TXCLK16 TXCLK16
IN–
IN+
TXDIN
[1]–
TXDIN
[1]+
TXDIN
[3]–
TXDIN
[3]+
TXDIN
[5]–
TXDIN
[5]+
TXDIN
[7]–
TXDIN
[7]+
TXDIN
[9]–
TXDIN
[9]+
TXDIN
[11]–
TXDIN
[11]+
P
TXCLK16 TXCLK16
OUT–
OUT+
TXDIN
[0]–
TXDIN
[0]+
TXDIN
[2]–
TXDIN
[2]+
TXDIN
[4]–
TXDIN
[4]+
TXDIN
[6]–
TXDIN
[6]+
TXDIN
[8]–
TXDIN
[8]+
TXDIN
[10]–
TXDIN
[10]+
Top View
Figure 7. Si5600 Pin Configuration (Transparent Top View)
18
13
Preliminary Rev. 0.31
Si5600
Pin Descriptions: Si5600
Pin Number(s)
Name
I/O
Signal Level
Description
M7
BWSEL
I
LVTTL
Bandwidth Select DSPLL.
This input selects loop bandwidth of the DSPLL.
BWSEL = 0: Loop bandwidth set to 12 kHz.
BWSEL = 1: Loop bandwidth set to 50 kHz.
F12
DLBK
I
LVTTL
Diagnostic Loopback.
When this input is active low the transmit clock
and data are looped back for output on RXDOUT,
RXCLK1 and RXCLK2. This pin should be held
high for normal operation.
K3
FIFOERR
O
LVTTL
FIFO Error.
This output is driven high when a FIFO overflow/
underflow has occurred. This output will stick
high until reset by asserting FIFORST.
M6
FIFORST
I
LVTTL
FIFO RESET.
This input when asserted high resets the read/
write FIFO pointers to their initial state.
B1, C1–2, D5–
11, D2, E11, E2,
F11, F1–2, G11,
G2, H11, H2,
J11, J1–4, K2,
K11, L5–11, L2,
M1–4
GND
GND
H12
LLBK
I
LVTTL
Line Loopback.
When this input is active low the recovered clock
and data are looped back for output on TXDOUT,
and TXCLKOUT. This pin should be held high for
normal operation.
G3
LOS
O
LVTTL
Loss-of-Signal.
This output is driven low when the peak-to-peak
signal amplitude is below threshold set via
LOSLVL.
C3
LOSLVL
I
Supply Ground.
LOS Threshold Level.
Applying an analog voltage to this pin allows
adjustment of the threshold used to declare LOS.
Tieing this input high disables LOS detection and
forces the LOS output high.
Preliminary Rev. 0.31
19
Si5600
Pin Number(s)
Name
I/O
Signal Level
Description
J12
LPTM
I
LVTTL
Loop Timed Operation.
When this input is forced high, the recovered
clock from the receiver is divided down and used
as the reference source for the transmit CMU.
The narrowband setting for the DSPLL CMU will
be sufficient to provide SONET compliant jitter
generation and transfer on the transmit data and
clock outputs (TXDOUT,TXCLKOUT). This pin
should be held low for normal operation.
E3
LTR
I
LVTTL
Lock-to-Reference
This input forces a stable output clock by locking
RXCLK1 and RXCLK2 to the provided reference.
Driving LTR low activates this feature.
C10, L4
NC
D4
PHASEADJ
I
G14, H14
REFCLK+,
REFCLK–
I
LVPECL
Differential Reference Clock.
The reference clock sets the operating frequency
of the PLL used to generate the high speed transmit clock. In addition, REFCLK sets the initial
operating frequency used by the onboard PLL for
clock and data recovery. The Si5600 will operate
with reference clock frequencies that are either
1/16th or 1/64th the serial data rate (nominally
155 MHz or 622 MHz).
H4
REFRATE
I
LVTTL
Reference Clock Select.
This input configures the Si5600 to operate with
one of two reference clock frequencies. If
REFRATE is held high, the device requires a reference clock that is 1/16 the serial data rate. If
REFRATE is low, a reference clock at 1/64 the
serial data rate is required.
L12
REFSEL
I
LVTTL
Reference Clock Selection.
This inputs selects the reference clock source
used by the CMU. When REFSEL = 0, the low
speed data input clock, TXCLK16IN, is used as
the CMU reference. When REFSEL = 1, the reference clock provided on REFCLK is used.
20
No Connect.
Reserved for device testing leave electrically
unconnected.
Sampling Phase Adjust.
Applying an analog voltage to this pin allows
adjustment of the sampling phase across the
data eye. Tieing this input high nominally centers
the sampling phase.
Preliminary Rev. 0.31
Si5600
Pin Number(s)
Name
I/O
Signal Level
Description
G4
RESET
I
LVTTL
Device Reset.
Forcing this input low for a at least 1 µs will cause
a device reset. For normal operation, this pin
should be held high.
C6–7, D3, E12,
F4, K4, M10–11,
M8
RSVD_GND
E4, G12
RSVD_VDD33
A2–3
RXCLK1+,
RXCLK1–
O
LVDS
Differential Clock Output 1.
The clock recovered from the signal present on
RXDIN is divided down by 16 and output on CLKOUT. In the absence of data, a stable clock on
RXCLK1 can be maintained by asserting LTR.
B2–3
RXCLK2+,
RXCLK2–
O
LVDS
Differential Clock Output 2.
An auxiliary output clock is provided on this pin
that may be a divided down version of the high
speed clock recovered from the signal present on
RXDIN. The divide factor used in generating
RXCLK2 is set via RXCLK2DIV.
C12
RXCLK2DIV
I
LVTTL
Clock Divider Select.
This input selects the divide factor used to generate the RXCLK2 output. When this input is driven
low, RXCLK2 is 1/16th the recovered high speed
clock. When driven high, RXCLK2 is 1/64th the
recovered high speed clock rate.
C8
RXCLK2DSBL
I
LVTTL
RXCLK2 Disable.
Driving this input high will disable the RXCLK2
output. This would be used to save power in
applications that do not require an auxiliary clock.
D1, E1
RXDIN+,
RXDIN–
I
High Speed
Differential
A4–14, B4–14,
C13–14, D13–
14, E13–14,
F13–14, G13,
H13
RXDOUT[15:0]+,
RXDOUT[15:0]–
O
LVDS
Differential Parallel Data Output.
The data recovered from the signal present on
RXDIN is demultiplexed and output as a 16-bit
parallel word via RXDOUT[15:0]. These outputs
are updated on the rising edge of RXCLK1.
F3
RXLOL
O
LVTTL
Loss-of-Lock.
This output is driven low when the recovered
clock frequency deviates from the reference
clock by the amount specified in Table 5.
Reserved Tie to Ground.
Must tie directly to GND for proper operation.
Reserved Tie to VDD33.
Must tie directly to VDD33 for proper operation.
Differential Data Input.
Clock and data are recovered from the high
speed data signal present on these pins.
Preliminary Rev. 0.31
21
Si5600
Pin Number(s)
Name
I/O
Signal Level
Description
D12
RXMSBSEL
I
LVTTL
Data Bus Receive Order.
This determines the order of the received data
bits on the output bus.
For RXMSBSEL = 0, the first data bit received is
output on RXDOUT[0] and following data bits are
output on RDOUT[1] through RXDOUT[15].
For RXMSBSEL = 1, the first data bit is output on
RXDOUT[15] and following data bits are output
on RXDOUT[14] through RXDOUT[0].
C11
RXREXT
C9
RXSQLCH
I
C4
SLICELVL
I
N1–2
TXCLK16IN+,
TXCLK16IN–
I
LVDS
Differential Data Clock Input.
The rising edge of this input clocks data present
on TXDIN into the device.
P1–2
TXCLK16OUT+,
TXCLK16OUT–
O
LVDS
Divided Down Output Clock.
This clock output is generated by dividing down
the high speed output clock, TXCLKOUT, by a
factor of 16. It is intended for use in counter
clocking schemes that transfer data between the
system ASIC and the Si5600.
K12
TXCLKDSBL
I
LVTTL
High Speed Clock Disable
When this input is high, the output driver for
TXCLKOUT is disabled. In applications that do
not require the output data clock, the output clock
driver should be disabled to save power.
G1, H1
TXCLKOUT+,
TXCLKOUT–
O
CML
High Speed Clock Output.
The high speed output clock, TXCLKOUT, is generated by the PLL in the clock multiplier unit. Its
frequency is nominally 16 or 64 times the
selected reference source.
22
External Bias Resistor.
This resistor is used by the receiver circuitry to
establish bias currents within the device. This pin
must be connected to GND through a 3.09 kΩ
(1%) resistor.
LVTTL
Data Squelch.
When this input is low the data on RXDOUT is
forced to 0. Set high for normal operation.
Slicing Level Adjustment.
Applying an analog voltage to this pin allows
adjustment of the slicing level applied to the input
data eye. Tieing this input high nominally sets the
slicing offset to 0.
Preliminary Rev. 0.31
Si5600
Pin Number(s)
Name
I/O
Signal Level
Description
J13–14, K13–
14, L13–14,
M13–14, N3–
14, P3–14
TXDIN[15:0]+,
TXDIN[15:0]–
I
LVDS
Differential Parallel Data Input.
The 16-bit data word present on these pins is
multiplexed into a high speed serial stream and
output on TXDOUT. The data on these inputs is
clocked into the device by the rising edge of
TXCLK16IN.
K1, L1
TXDOUT+,
TXDOUT–
O
CML
Differential High Speed Data Output.
The 16-bit word input on TXDIN[15:0] is multiplexed into a high speed serial stream that is output on these pins. Input data is multiplexed in
sequence from TXDIN0 to TXDIN15 with TXDIN0
transmitted first. This output is updated by the rising edge of TXCLKOUT.
M5
TXLOL
O
LVTTL
CMU Loss-of-Lock.
The output is asserted low when the CMU is not
phase locked to the selected reference source.
M9
TXMSBSEL
I
LVTTL
Data Bus Transmit Order.
For TXMSBSEL = 0, data on TXDIN[0] is transmitted first followed by TXDIN[1] through
TXDIN[15].
For TXMSBSEL = 1, TXDIN[15] is transmitted
first followed by TXDIN[14] through TXDIN[0].
L3
TXREXT
M12
TXSQLCH
I
LVTTL
Transmit Data Squelch.
If TXSQLCH is asserted low, the output data
stream on TXDOUT will be forced to 0s. If
TXSQLCH = 1, TX squelching is turned off.
E5–10, F5–10,
G5–10, H5–10,
J5–10, K5–10
VDD
VDD
1.8 V
Supply Voltage.
Nominally 1.8 V.
External Bias Resistor.
This resistor is used by the transmitter circuitry to
establish bias currents within the device. This pin
must be connected to GND through a 3.09 kΩ
(1%) resistor.
Preliminary Rev. 0.31
23
Si5600
Pin Number(s)
Name
I/O
H3
VDD33
VDD33
C5
VREF
O
24
Signal Level
Description
1.8 V or 3.3 V Digital Output Supply.
Must be tied to either 1.8 V or 3.3 V. When tied to
3.3 V, LVTTL compatible output voltage swings
on RXLOL and LOS, TXLOL, FIFOERR are supported.
Voltage Ref
Voltage Reference.
The Si5600 provides an output voltage reference
that can be used by an external circuit to set the
LOS threshold, slicing level, or sampling phase
adjustment. The equivalent resistance between
this pin and GND should not be less than 10 kΩ.
The reference voltage is nominally 1.25 V.
Preliminary Rev. 0.31
Si5600
Ordering Guide
Table 9. Ordering Guide
Part Number
Package
Temperature
Si5600-BC
195 BGA
–40°C to 85°C
Preliminary Rev. 0.31
25
Si5600
Package Outline
Figure 8 illustrates the package details for the Si5600. Table 10 lists the values for the dimensions shown in the
illustration.
P
N
M
L
K
J
H
G
F
E
D
C
B
A
1 2 3 4 5 6 7 8 9 10 11 12 13 14
Figure 8. 195-Ball Grid Array (BGA)
Table 10. Package Diagram Dimensions (mm)
26
Symbol
Min
Nom
Max
A
3.50
3.65
3.80
A1
0.65
0.70
0.75
A2
1.35
1.45
1.55
b
0.65
0.70
0.75
D
14.90
15.00
15.10
D1
—
13.00
—
e
—
1.00
—
L
12.95
13.00
13.05
S
—
0.50
—
Preliminary Rev. 0.31
Si5600
NOTES:
Preliminary Rev. 0.31
27
Si5600
Contact Information
Silicon Laboratories Inc.
4635 Boston Lane
Austin, TX 78735
Tel: 1+(512) 416-8500
Fax: 1+(512) 416-9669
Toll Free: 1+(877) 444-3032
Email: [email protected]
Internet: www.silabs.com
The information in this document is believed to be accurate in all respects at the time of publication but is subject to change without notice.
Silicon Laboratories assumes no responsibility for errors and omissions, and disclaims responsibility for any consequences resulting from
the use of information included herein. Additionally, Silicon Laboratories assumes no responsibility for the functioning of undescribed features
or parameters. Silicon Laboratories reserves the right to make changes without further notice. Silicon Laboratories makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Silicon Laboratories assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. Silicon Laboratories products are not designed, intended, or authorized for use in applications intended to
support or sustain life, or for any other application in which the failure of the Silicon Laboratories product could create a situation where personal injury or death may occur. Should Buyer purchase or use Silicon Laboratories products for any such unintended or unauthorized application, Buyer shall indemnify and hold Silicon Laboratories harmless against all claims and damages.
Silicon Laboratories, Silicon Labs, SiPHY, and DSPLL are trademarks of Silicon Laboratories Inc.
Other products or brandnames mentioned herein are trademarks or registered trademarks of their respective holders.
28
Preliminary Rev. 0.31